Ambipolar Nature Accelerates Dual-Functionality on Ni/Ni3N@NC for Simultaneous Hydrogen and Oxygen Evolution in Electrochemical Water Splitting System

Gnanaprakasam Janani; Subramani Surendran; Dae Jun Moon; Poonchi Sivasankaran Ramesh; Joon Young Kim; Yoongu Lim; Krishnan Veeramani; Shivraj Mahadik; Sebastian Cyril Jesudass; Jinuk Choi; Il Goo Kim; Pildo Jung; Heechae Choi; Gibum Kwon; Kyoungsuk Jin; Jung kyu Kim; Yong Il Park; Jaeyeong Heo; Kootak Hong; Young Soo Kang; Uk Sim

doi:10.1002/adsu.202400059

Ambipolar Nature Accelerates Dual-Functionality on Ni/Ni3N@NC for Simultaneous Hydrogen and Oxygen Evolution in Electrochemical Water Splitting System

Gnanaprakasam Janani, Subramani Surendran, Dae Jun Moon, Poonchi Sivasankaran Ramesh, Joon Young Kim, Yoongu Lim, Krishnan Veeramani, Shivraj Mahadik, Sebastian Cyril Jesudass, Jinuk Choi, Il Goo Kim, Pildo Jung, Heechae Choi, Gibum Kwon, Kyoungsuk Jin, Jung kyu Kim, Yong Il Park, Jaeyeong Heo, Kootak Hong, Young Soo Kang^*Uk Sim^*

^*Corresponding author for this work

Department of Chemistry and Materials Science

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Abstract Metal nitrides with extraordinary electrochemical characteristics established widespread applications in energy devices. Inspired by the recent research on promising heterostructured catalysts, the preparation of a nitride-based heterostructure via a facile approach involving a one-step nitridation process is revisited. An innovative Ni/Ni3N is decorated on nitrogen-doped carbon (NC) and evaluated for its dual-functionality as a catalyst in the electrochemical hydrogen evolution reaction (EHER) and the electrochemical oxygen evolution reaction (EOER). In contrast to Ni@NC and pristine NC, Ni/Ni3N@NC with the well-constructed NC significantly enhanced its catalytic performance toward EHER and EOER in a water electrolyzer. The water electrolyzer consists of Ni/Ni3N@NC as both the anode and cathode achieve a current density of 10 mA cm−2 with a remarkably low voltage of 1.52 V. The designed catalyst takes full advantage of its heterostructure and ambipolar behavior leading to the presence of active sites for EOER and EHER, as confirmed by in-situ Raman analysis. These results provide important guidance on designing an efficient and cost-effective heterostructured dual-functional catalyst as well as revealing the mechanism at the interface between the surface of an ambipolar catalyst and electrolyte.

Original language	Undefined/Unknown
Pages (from-to)	2400059
Number of pages	1
Journal	Advanced Sustainable Systems
Volume	n/a
Issue number	n/a
DOIs	https://doi.org/10.1002/adsu.202400059
Publication status	Published - 17 Aug 2024

Keywords

ambipolar
dual-functional catalyst
in-situ analysis
nickel nitride
nitrogen-doped carbon

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/adsu.202400059

https://onlinelibrary.wiley.com/doi/abs/10.1002/adsu.202400059

Cite this

Janani, G., Surendran, S., Moon, D. J., Ramesh, P. S., Kim, J. Y., Lim, Y., Veeramani, K., Mahadik, S., Jesudass, S. C., Choi, J., Kim, I. G., Jung, P., Choi, H., Kwon, G., Jin, K., Kim, J. K., Park, Y. I., Heo, J., Hong, K., ... Sim, U. (2024). Ambipolar Nature Accelerates Dual-Functionality on Ni/Ni3N@NC for Simultaneous Hydrogen and Oxygen Evolution in Electrochemical Water Splitting System. Advanced Sustainable Systems, n/a(n/a), 2400059. https://doi.org/10.1002/adsu.202400059

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title = "Ambipolar Nature Accelerates Dual-Functionality on Ni/Ni3N@NC for Simultaneous Hydrogen and Oxygen Evolution in Electrochemical Water Splitting System",

abstract = "Abstract Metal nitrides with extraordinary electrochemical characteristics established widespread applications in energy devices. Inspired by the recent research on promising heterostructured catalysts, the preparation of a nitride-based heterostructure via a facile approach involving a one-step nitridation process is revisited. An innovative Ni/Ni3N is decorated on nitrogen-doped carbon (NC) and evaluated for its dual-functionality as a catalyst in the electrochemical hydrogen evolution reaction (EHER) and the electrochemical oxygen evolution reaction (EOER). In contrast to Ni@NC and pristine NC, Ni/Ni3N@NC with the well-constructed NC significantly enhanced its catalytic performance toward EHER and EOER in a water electrolyzer. The water electrolyzer consists of Ni/Ni3N@NC as both the anode and cathode achieve a current density of 10 mA cm−2 with a remarkably low voltage of 1.52 V. The designed catalyst takes full advantage of its heterostructure and ambipolar behavior leading to the presence of active sites for EOER and EHER, as confirmed by in-situ Raman analysis. These results provide important guidance on designing an efficient and cost-effective heterostructured dual-functional catalyst as well as revealing the mechanism at the interface between the surface of an ambipolar catalyst and electrolyte.",

keywords = "ambipolar, dual-functional catalyst, in-situ analysis, nickel nitride, nitrogen-doped carbon",

author = "Gnanaprakasam Janani and Subramani Surendran and Moon, {Dae Jun} and Ramesh, {Poonchi Sivasankaran} and Kim, {Joon Young} and Yoongu Lim and Krishnan Veeramani and Shivraj Mahadik and Jesudass, {Sebastian Cyril} and Jinuk Choi and Kim, {Il Goo} and Pildo Jung and Heechae Choi and Gibum Kwon and Kyoungsuk Jin and Kim, {Jung kyu} and Park, {Yong Il} and Jaeyeong Heo and Kootak Hong and Kang, {Young Soo} and Uk Sim",

year = "2024",

month = aug,

day = "17",

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Janani, G, Surendran, S, Moon, DJ, Ramesh, PS, Kim, JY, Lim, Y, Veeramani, K, Mahadik, S, Jesudass, SC, Choi, J, Kim, IG, Jung, P, Choi, H, Kwon, G, Jin, K, Kim, JK, Park, YI, Heo, J, Hong, K, Kang, YS & Sim, U 2024, 'Ambipolar Nature Accelerates Dual-Functionality on Ni/Ni3N@NC for Simultaneous Hydrogen and Oxygen Evolution in Electrochemical Water Splitting System', Advanced Sustainable Systems, vol. n/a, no. n/a, pp. 2400059. https://doi.org/10.1002/adsu.202400059

TY - JOUR

T1 - Ambipolar Nature Accelerates Dual-Functionality on Ni/Ni3N@NC for Simultaneous Hydrogen and Oxygen Evolution in Electrochemical Water Splitting System

AU - Janani, Gnanaprakasam

AU - Surendran, Subramani

AU - Moon, Dae Jun

AU - Ramesh, Poonchi Sivasankaran

AU - Kim, Joon Young

AU - Lim, Yoongu

AU - Veeramani, Krishnan

AU - Mahadik, Shivraj

AU - Jesudass, Sebastian Cyril

AU - Choi, Jinuk

AU - Kim, Il Goo

AU - Jung, Pildo

AU - Choi, Heechae

AU - Kwon, Gibum

AU - Jin, Kyoungsuk

AU - Kim, Jung kyu

AU - Park, Yong Il

AU - Heo, Jaeyeong

AU - Hong, Kootak

AU - Kang, Young Soo

AU - Sim, Uk

PY - 2024/8/17

Y1 - 2024/8/17

N2 - Abstract Metal nitrides with extraordinary electrochemical characteristics established widespread applications in energy devices. Inspired by the recent research on promising heterostructured catalysts, the preparation of a nitride-based heterostructure via a facile approach involving a one-step nitridation process is revisited. An innovative Ni/Ni3N is decorated on nitrogen-doped carbon (NC) and evaluated for its dual-functionality as a catalyst in the electrochemical hydrogen evolution reaction (EHER) and the electrochemical oxygen evolution reaction (EOER). In contrast to Ni@NC and pristine NC, Ni/Ni3N@NC with the well-constructed NC significantly enhanced its catalytic performance toward EHER and EOER in a water electrolyzer. The water electrolyzer consists of Ni/Ni3N@NC as both the anode and cathode achieve a current density of 10 mA cm−2 with a remarkably low voltage of 1.52 V. The designed catalyst takes full advantage of its heterostructure and ambipolar behavior leading to the presence of active sites for EOER and EHER, as confirmed by in-situ Raman analysis. These results provide important guidance on designing an efficient and cost-effective heterostructured dual-functional catalyst as well as revealing the mechanism at the interface between the surface of an ambipolar catalyst and electrolyte.

AB - Abstract Metal nitrides with extraordinary electrochemical characteristics established widespread applications in energy devices. Inspired by the recent research on promising heterostructured catalysts, the preparation of a nitride-based heterostructure via a facile approach involving a one-step nitridation process is revisited. An innovative Ni/Ni3N is decorated on nitrogen-doped carbon (NC) and evaluated for its dual-functionality as a catalyst in the electrochemical hydrogen evolution reaction (EHER) and the electrochemical oxygen evolution reaction (EOER). In contrast to Ni@NC and pristine NC, Ni/Ni3N@NC with the well-constructed NC significantly enhanced its catalytic performance toward EHER and EOER in a water electrolyzer. The water electrolyzer consists of Ni/Ni3N@NC as both the anode and cathode achieve a current density of 10 mA cm−2 with a remarkably low voltage of 1.52 V. The designed catalyst takes full advantage of its heterostructure and ambipolar behavior leading to the presence of active sites for EOER and EHER, as confirmed by in-situ Raman analysis. These results provide important guidance on designing an efficient and cost-effective heterostructured dual-functional catalyst as well as revealing the mechanism at the interface between the surface of an ambipolar catalyst and electrolyte.

KW - ambipolar

KW - dual-functional catalyst

KW - in-situ analysis

KW - nickel nitride

KW - nitrogen-doped carbon

U2 - 10.1002/adsu.202400059

DO - 10.1002/adsu.202400059

M3 - 文章

SN - 2366-7486

VL - n/a

SP - 2400059

JO - Advanced Sustainable Systems

JF - Advanced Sustainable Systems

IS - n/a

ER -